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gerrit-public.fairphone.software / platform / vendor / qcom-opensource / wlan / qca-wifi-host-cmn / 690f7d094e7c93eacd5ac5a60c1ab01011dcaca9 / . / hal / wifi3.0 / hal_api.h
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/*
* Copyright (c) 2016-2020 The Linux Foundation. All rights reserved.
*
* Permission to use, copy, modify, and/or distribute this software for
* any purpose with or without fee is hereby granted, provided that the
* above copyright notice and this permission notice appear in all
* copies.
*
* THE SOFTWARE IS PROVIDED "AS IS" AND THE AUTHOR DISCLAIMS ALL
* WARRANTIES WITH REGARD TO THIS SOFTWARE INCLUDING ALL IMPLIED
* WARRANTIES OF MERCHANTABILITY AND FITNESS. IN NO EVENT SHALL THE
* AUTHOR BE LIABLE FOR ANY SPECIAL, DIRECT, INDIRECT, OR CONSEQUENTIAL
* DAMAGES OR ANY DAMAGES WHATSOEVER RESULTING FROM LOSS OF USE, DATA OR
* PROFITS, WHETHER IN AN ACTION OF CONTRACT, NEGLIGENCE OR OTHER
* TORTIOUS ACTION, ARISING OUT OF OR IN CONNECTION WITH THE USE OR
* PERFORMANCE OF THIS SOFTWARE.
*/
#ifndef _HAL_API_H_
#define _HAL_API_H_
#include "qdf_types.h"
#include "qdf_util.h"
#include "qdf_atomic.h"
#include "hal_internal.h"
#include "hif.h"
#include "hif_io32.h"
#include "qdf_platform.h"
/* calculate the register address offset from bar0 of shadow register x */
#if defined(QCA_WIFI_QCA6390) || defined(QCA_WIFI_QCA6490) || \
defined(QCA_WIFI_QCA6750)
#define SHADOW_REGISTER_START_ADDRESS_OFFSET 0x000008FC
#define SHADOW_REGISTER_END_ADDRESS_OFFSET \
((SHADOW_REGISTER_START_ADDRESS_OFFSET) + (4 * (MAX_SHADOW_REGISTERS)))
#define SHADOW_REGISTER(x) ((SHADOW_REGISTER_START_ADDRESS_OFFSET) + (4 * (x)))
#elif defined(QCA_WIFI_QCA6290) || defined(QCA_WIFI_QCN9000)
#define SHADOW_REGISTER_START_ADDRESS_OFFSET 0x00003024
#define SHADOW_REGISTER_END_ADDRESS_OFFSET \
((SHADOW_REGISTER_START_ADDRESS_OFFSET) + (4 * (MAX_SHADOW_REGISTERS)))
#define SHADOW_REGISTER(x) ((SHADOW_REGISTER_START_ADDRESS_OFFSET) + (4 * (x)))
#else
#define SHADOW_REGISTER(x) 0
#endif /* QCA_WIFI_QCA6390 || QCA_WIFI_QCA6490 || QCA_WIFI_QCA6750 */
#define MAX_UNWINDOWED_ADDRESS 0x80000
#if defined(QCA_WIFI_QCA6390) || defined(QCA_WIFI_QCA6490) || \
defined(QCA_WIFI_QCN9000) || defined(QCA_WIFI_QCA6750)
#define WINDOW_ENABLE_BIT 0x40000000
#else
#define WINDOW_ENABLE_BIT 0x80000000
#endif
#define WINDOW_REG_ADDRESS 0x310C
#define WINDOW_SHIFT 19
#define WINDOW_VALUE_MASK 0x3F
#define WINDOW_START MAX_UNWINDOWED_ADDRESS
#define WINDOW_RANGE_MASK 0x7FFFF
/*
* BAR + 4K is always accessible, any access outside this
* space requires force wake procedure.
* OFFSET = 4K - 32 bytes = 0xFE0
*/
#define MAPPED_REF_OFF 0xFE0
/**
* hal_ring_desc - opaque handle for DP ring descriptor
*/
struct hal_ring_desc;
typedef struct hal_ring_desc *hal_ring_desc_t;
/**
* hal_link_desc - opaque handle for DP link descriptor
*/
struct hal_link_desc;
typedef struct hal_link_desc *hal_link_desc_t;
/**
* hal_rxdma_desc - opaque handle for DP rxdma dst ring descriptor
*/
struct hal_rxdma_desc;
typedef struct hal_rxdma_desc *hal_rxdma_desc_t;
/**
* hal_buff_addrinfo - opaque handle for DP buffer address info
*/
struct hal_buff_addrinfo;
typedef struct hal_buff_addrinfo *hal_buff_addrinfo_t;
#ifdef ENABLE_VERBOSE_DEBUG
static inline void
hal_set_verbose_debug(bool flag)
{
is_hal_verbose_debug_enabled = flag;
}
#endif
#ifdef ENABLE_HAL_SOC_STATS
#define HAL_STATS_INC(_handle, _field, _delta) \
{ \
if (likely(_handle)) \
_handle->stats._field += _delta; \
}
#else
#define HAL_STATS_INC(_handle, _field, _delta)
#endif
#ifdef ENABLE_HAL_REG_WR_HISTORY
#define HAL_REG_WRITE_FAIL_HIST_ADD(hal_soc, offset, wr_val, rd_val) \
hal_reg_wr_fail_history_add(hal_soc, offset, wr_val, rd_val)
void hal_reg_wr_fail_history_add(struct hal_soc *hal_soc,
uint32_t offset,
uint32_t wr_val,
uint32_t rd_val);
static inline int hal_history_get_next_index(qdf_atomic_t *table_index,
int array_size)
{
int record_index = qdf_atomic_inc_return(table_index);
return record_index & (array_size - 1);
}
#else
#define HAL_REG_WRITE_FAIL_HIST_ADD(hal_soc, offset, wr_val, rd_val) \
hal_err("write failed at reg offset 0x%x, write 0x%x read 0x%x\n", \
offset, \
wr_val, \
rd_val)
#endif
/**
* hal_reg_write_result_check() - check register writing result
* @hal_soc: HAL soc handle
* @offset: register offset to read
* @exp_val: the expected value of register
* @ret_confirm: result confirm flag
*
* Return: none
*/
static inline void hal_reg_write_result_check(struct hal_soc *hal_soc,
uint32_t offset,
uint32_t exp_val)
{
uint32_t value;
value = qdf_ioread32(hal_soc->dev_base_addr + offset);
if (exp_val != value) {
HAL_REG_WRITE_FAIL_HIST_ADD(hal_soc, offset, exp_val, value);
HAL_STATS_INC(hal_soc, reg_write_fail, 1);
}
}
#if !defined(QCA_WIFI_QCA6390) && !defined(QCA_WIFI_QCA6490) || \
!defined(QCA_WIFI_QCA6750)
static inline void hal_lock_reg_access(struct hal_soc *soc,
unsigned long *flags)
{
qdf_spin_lock_irqsave(&soc->register_access_lock);
}
static inline void hal_unlock_reg_access(struct hal_soc *soc,
unsigned long *flags)
{
qdf_spin_unlock_irqrestore(&soc->register_access_lock);
}
#else
static inline void hal_lock_reg_access(struct hal_soc *soc,
unsigned long *flags)
{
pld_lock_reg_window(soc->qdf_dev->dev, flags);
}
static inline void hal_unlock_reg_access(struct hal_soc *soc,
unsigned long *flags)
{
pld_unlock_reg_window(soc->qdf_dev->dev, flags);
}
#endif
#ifdef PCIE_REG_WINDOW_LOCAL_NO_CACHE
static inline void hal_select_window(struct hal_soc *hal_soc, uint32_t offset)
{
uint32_t window = (offset >> WINDOW_SHIFT) & WINDOW_VALUE_MASK;
qdf_iowrite32(hal_soc->dev_base_addr + WINDOW_REG_ADDRESS,
WINDOW_ENABLE_BIT | window);
hal_soc->register_window = window;
}
/**
* hal_select_window_confirm() - write remap window register and
check writing result
*
*/
static inline void hal_select_window_confirm(struct hal_soc *hal_soc,
uint32_t offset)
{
uint32_t window = (offset >> WINDOW_SHIFT) & WINDOW_VALUE_MASK;
qdf_iowrite32(hal_soc->dev_base_addr + WINDOW_REG_ADDRESS,
WINDOW_ENABLE_BIT | window);
hal_soc->register_window = window;
hal_reg_write_result_check(hal_soc, WINDOW_REG_ADDRESS,
WINDOW_ENABLE_BIT | window);
}
#else
static inline void hal_select_window(struct hal_soc *hal_soc, uint32_t offset)
{
uint32_t window = (offset >> WINDOW_SHIFT) & WINDOW_VALUE_MASK;
if (window != hal_soc->register_window) {
qdf_iowrite32(hal_soc->dev_base_addr + WINDOW_REG_ADDRESS,
WINDOW_ENABLE_BIT | window);
hal_soc->register_window = window;
}
}
static inline void hal_select_window_confirm(struct hal_soc *hal_soc,
uint32_t offset)
{
uint32_t window = (offset >> WINDOW_SHIFT) & WINDOW_VALUE_MASK;
if (window != hal_soc->register_window) {
qdf_iowrite32(hal_soc->dev_base_addr + WINDOW_REG_ADDRESS,
WINDOW_ENABLE_BIT | window);
hal_soc->register_window = window;
hal_reg_write_result_check(
hal_soc,
WINDOW_REG_ADDRESS,
WINDOW_ENABLE_BIT | window);
}
}
#endif
static inline qdf_iomem_t hal_get_window_address(struct hal_soc *hal_soc,
qdf_iomem_t addr)
{
return hal_soc->ops->hal_get_window_address(hal_soc, addr);
}
/**
* hal_write32_mb() - Access registers to update configuration
* @hal_soc: hal soc handle
* @offset: offset address from the BAR
* @value: value to write
*
* Return: None
*
* Description: Register address space is split below:
* SHADOW REGION UNWINDOWED REGION WINDOWED REGION
* |--------------------|-------------------|------------------|
* BAR NO FORCE WAKE BAR+4K FORCE WAKE BAR+512K FORCE WAKE
*
* 1. Any access to the shadow region, doesn't need force wake
* and windowing logic to access.
* 2. Any access beyond BAR + 4K:
* If init_phase enabled, no force wake is needed and access
* should be based on windowed or unwindowed access.
* If init_phase disabled, force wake is needed and access
* should be based on windowed or unwindowed access.
*
* note1: WINDOW_RANGE_MASK = (1 << WINDOW_SHIFT) -1
* note2: 1 << WINDOW_SHIFT = MAX_UNWINDOWED_ADDRESS
* note3: WINDOW_VALUE_MASK = big enough that trying to write past
* that window would be a bug
*/
#if !defined(QCA_WIFI_QCA6390) && !defined(QCA_WIFI_QCA6490) && \
!defined(QCA_WIFI_QCA6750)
static inline void hal_write32_mb(struct hal_soc *hal_soc, uint32_t offset,
uint32_t value)
{
unsigned long flags;
qdf_iomem_t new_addr;
if (!hal_soc->use_register_windowing ||
offset < MAX_UNWINDOWED_ADDRESS) {
qdf_iowrite32(hal_soc->dev_base_addr + offset, value);
} else if (hal_soc->static_window_map) {
new_addr = hal_get_window_address(hal_soc,
hal_soc->dev_base_addr + offset);
qdf_iowrite32(new_addr, value);
} else {
hal_lock_reg_access(hal_soc, &flags);
hal_select_window(hal_soc, offset);
qdf_iowrite32(hal_soc->dev_base_addr + WINDOW_START +
(offset & WINDOW_RANGE_MASK), value);
hal_unlock_reg_access(hal_soc, &flags);
}
}
/**
* hal_write_address_32_mb - write a value to a register
*
*/
static inline
void hal_write_address_32_mb(struct hal_soc *hal_soc,
qdf_iomem_t addr, uint32_t value)
{
uint32_t offset;
qdf_iomem_t new_addr;
if (!hal_soc->use_register_windowing)
return qdf_iowrite32(addr, value);
offset = addr - hal_soc->dev_base_addr;
if (hal_soc->static_window_map) {
new_addr = hal_get_window_address(hal_soc, addr);
return qdf_iowrite32(new_addr, value);
}
hal_write32_mb(hal_soc, offset, value);
}
#define hal_write32_mb_confirm(_hal_soc, _offset, _value) \
hal_write32_mb(_hal_soc, _offset, _value)
#else
static inline void hal_write32_mb(struct hal_soc *hal_soc, uint32_t offset,
uint32_t value)
{
int ret;
unsigned long flags;
/* Region < BAR + 4K can be directly accessed */
if (offset < MAPPED_REF_OFF) {
qdf_iowrite32(hal_soc->dev_base_addr + offset, value);
return;
}
/* Region greater than BAR + 4K */
if (!hal_soc->init_phase) {
ret = hif_force_wake_request(hal_soc->hif_handle);
if (ret) {
hal_err("Wake up request failed");
qdf_check_state_before_panic();
return;
}
}
if (!hal_soc->use_register_windowing ||
offset < MAX_UNWINDOWED_ADDRESS) {
qdf_iowrite32(hal_soc->dev_base_addr + offset, value);
} else {
hal_lock_reg_access(hal_soc, &flags);
hal_select_window(hal_soc, offset);
qdf_iowrite32(hal_soc->dev_base_addr + WINDOW_START +
(offset & WINDOW_RANGE_MASK), value);
hal_unlock_reg_access(hal_soc, &flags);
}
if (!hal_soc->init_phase) {
ret = hif_force_wake_release(hal_soc->hif_handle);
if (ret) {
hal_err("Wake up release failed");
qdf_check_state_before_panic();
return;
}
}
}
/**
* hal_write32_mb_confirm() - write register and check wirting result
*
*/
static inline void hal_write32_mb_confirm(struct hal_soc *hal_soc,
uint32_t offset,
uint32_t value)
{
int ret;
unsigned long flags;
/* Region < BAR + 4K can be directly accessed */
if (offset < MAPPED_REF_OFF) {
qdf_iowrite32(hal_soc->dev_base_addr + offset, value);
return;
}
/* Region greater than BAR + 4K */
if (!hal_soc->init_phase) {
ret = hif_force_wake_request(hal_soc->hif_handle);
if (ret) {
hal_err("Wake up request failed");
qdf_check_state_before_panic();
return;
}
}
if (!hal_soc->use_register_windowing ||
offset < MAX_UNWINDOWED_ADDRESS) {
qdf_iowrite32(hal_soc->dev_base_addr + offset, value);
hal_reg_write_result_check(hal_soc, offset,
value);
} else {
hal_lock_reg_access(hal_soc, &flags);
hal_select_window_confirm(hal_soc, offset);
qdf_iowrite32(hal_soc->dev_base_addr + WINDOW_START +
(offset & WINDOW_RANGE_MASK), value);
hal_reg_write_result_check(
hal_soc,
WINDOW_START + (offset & WINDOW_RANGE_MASK),
value);
hal_unlock_reg_access(hal_soc, &flags);
}
if (!hal_soc->init_phase) {
ret = hif_force_wake_release(hal_soc->hif_handle);
if (ret) {
hal_err("Wake up release failed");
qdf_check_state_before_panic();
return;
}
}
}
/**
* hal_write_address_32_mb - write a value to a register
*
*/
static inline
void hal_write_address_32_mb(struct hal_soc *hal_soc,
qdf_iomem_t addr, uint32_t value, bool wr_confirm)
{
uint32_t offset;
if (!hal_soc->use_register_windowing)
return qdf_iowrite32(addr, value);
offset = addr - hal_soc->dev_base_addr;
if (qdf_unlikely(wr_confirm))
hal_write32_mb_confirm(hal_soc, offset, value);
else
hal_write32_mb(hal_soc, offset, value);
}
#endif
#ifdef DP_HAL_MULTIWINDOW_DIRECT_ACCESS
static inline void hal_srng_write_address_32_mb(struct hal_soc *hal_soc,
struct hal_srng *srng,
void __iomem *addr,
uint32_t value)
{
qdf_iowrite32(addr, value);
}
#elif defined(FEATURE_HAL_DELAYED_REG_WRITE)
static inline void hal_srng_write_address_32_mb(struct hal_soc *hal_soc,
struct hal_srng *srng,
void __iomem *addr,
uint32_t value)
{
hal_delayed_reg_write(hal_soc, srng, addr, value);
}
#else
static inline void hal_srng_write_address_32_mb(struct hal_soc *hal_soc,
struct hal_srng *srng,
void __iomem *addr,
uint32_t value)
{
hal_write_address_32_mb(hal_soc, addr, value, false);
}
#endif
#if !defined(QCA_WIFI_QCA6390) && !defined(QCA_WIFI_QCA6490) && \
!defined(QCA_WIFI_QCA6750)
/**
* hal_read32_mb() - Access registers to read configuration
* @hal_soc: hal soc handle
* @offset: offset address from the BAR
* @value: value to write
*
* Description: Register address space is split below:
* SHADOW REGION UNWINDOWED REGION WINDOWED REGION
* |--------------------|-------------------|------------------|
* BAR NO FORCE WAKE BAR+4K FORCE WAKE BAR+512K FORCE WAKE
*
* 1. Any access to the shadow region, doesn't need force wake
* and windowing logic to access.
* 2. Any access beyond BAR + 4K:
* If init_phase enabled, no force wake is needed and access
* should be based on windowed or unwindowed access.
* If init_phase disabled, force wake is needed and access
* should be based on windowed or unwindowed access.
*
* Return: < 0 for failure/>= 0 for success
*/
static inline uint32_t hal_read32_mb(struct hal_soc *hal_soc, uint32_t offset)
{
uint32_t ret;
unsigned long flags;
qdf_iomem_t new_addr;
if (!hal_soc->use_register_windowing ||
offset < MAX_UNWINDOWED_ADDRESS) {
return qdf_ioread32(hal_soc->dev_base_addr + offset);
} else if (hal_soc->static_window_map) {
new_addr = hal_get_window_address(hal_soc, hal_soc->dev_base_addr + offset);
return qdf_ioread32(new_addr);
}
hal_lock_reg_access(hal_soc, &flags);
hal_select_window(hal_soc, offset);
ret = qdf_ioread32(hal_soc->dev_base_addr + WINDOW_START +
(offset & WINDOW_RANGE_MASK));
hal_unlock_reg_access(hal_soc, &flags);
return ret;
}
#else
static
uint32_t hal_read32_mb(struct hal_soc *hal_soc, uint32_t offset)
{
uint32_t ret;
unsigned long flags;
/* Region < BAR + 4K can be directly accessed */
if (offset < MAPPED_REF_OFF)
return qdf_ioread32(hal_soc->dev_base_addr + offset);
if ((!hal_soc->init_phase) &&
hif_force_wake_request(hal_soc->hif_handle)) {
hal_err("Wake up request failed");
qdf_check_state_before_panic();
return 0;
}
if (!hal_soc->use_register_windowing ||
offset < MAX_UNWINDOWED_ADDRESS) {
ret = qdf_ioread32(hal_soc->dev_base_addr + offset);
} else {
hal_lock_reg_access(hal_soc, &flags);
hal_select_window(hal_soc, offset);
ret = qdf_ioread32(hal_soc->dev_base_addr + WINDOW_START +
(offset & WINDOW_RANGE_MASK));
hal_unlock_reg_access(hal_soc, &flags);
}
if ((!hal_soc->init_phase) &&
hif_force_wake_release(hal_soc->hif_handle)) {
hal_err("Wake up release failed");
qdf_check_state_before_panic();
return 0;
}
return ret;
}
#endif
#ifdef FEATURE_HAL_DELAYED_REG_WRITE
/**
* hal_dump_reg_write_srng_stats() - dump SRNG reg write stats
* @hal_soc: HAL soc handle
*
* Return: none
*/
void hal_dump_reg_write_srng_stats(hal_soc_handle_t hal_soc_hdl);
/**
* hal_dump_reg_write_stats() - dump reg write stats
* @hal_soc: HAL soc handle
*
* Return: none
*/
void hal_dump_reg_write_stats(hal_soc_handle_t hal_soc_hdl);
#else
static inline void hal_dump_reg_write_srng_stats(hal_soc_handle_t hal_soc_hdl)
{
}
static inline void hal_dump_reg_write_stats(hal_soc_handle_t hal_soc_hdl)
{
}
#endif
/**
* hal_read_address_32_mb() - Read 32-bit value from the register
* @soc: soc handle
* @addr: register address to read
*
* Return: 32-bit value
*/
static inline
uint32_t hal_read_address_32_mb(struct hal_soc *soc,
qdf_iomem_t addr)
{
uint32_t offset;
uint32_t ret;
qdf_iomem_t new_addr;
if (!soc->use_register_windowing)
return qdf_ioread32(addr);
offset = addr - soc->dev_base_addr;
if (soc->static_window_map) {
new_addr = hal_get_window_address(soc, addr);
return qdf_ioread32(new_addr);
}
ret = hal_read32_mb(soc, offset);
return ret;
}
/**
* hal_attach - Initialize HAL layer
* @hif_handle: Opaque HIF handle
* @qdf_dev: QDF device
*
* Return: Opaque HAL SOC handle
* NULL on failure (if given ring is not available)
*
* This function should be called as part of HIF initialization (for accessing
* copy engines). DP layer will get hal_soc handle using hif_get_hal_handle()
*/
void *hal_attach(struct hif_opaque_softc *hif_handle, qdf_device_t qdf_dev);
/**
* hal_detach - Detach HAL layer
* @hal_soc: HAL SOC handle
*
* This function should be called as part of HIF detach
*
*/
extern void hal_detach(void *hal_soc);
/* SRNG type to be passed in APIs hal_srng_get_entrysize and hal_srng_setup */
enum hal_ring_type {
REO_DST = 0,
REO_EXCEPTION = 1,
REO_REINJECT = 2,
REO_CMD = 3,
REO_STATUS = 4,
TCL_DATA = 5,
TCL_CMD = 6,
TCL_STATUS = 7,
CE_SRC = 8,
CE_DST = 9,
CE_DST_STATUS = 10,
WBM_IDLE_LINK = 11,
SW2WBM_RELEASE = 12,
WBM2SW_RELEASE = 13,
RXDMA_BUF = 14,
RXDMA_DST = 15,
RXDMA_MONITOR_BUF = 16,
RXDMA_MONITOR_STATUS = 17,
RXDMA_MONITOR_DST = 18,
RXDMA_MONITOR_DESC = 19,
DIR_BUF_RX_DMA_SRC = 20,
#ifdef WLAN_FEATURE_CIF_CFR
WIFI_POS_SRC,
#endif
MAX_RING_TYPES
};
#define HAL_SRNG_LMAC_RING 0x80000000
/* SRNG flags passed in hal_srng_params.flags */
#define HAL_SRNG_MSI_SWAP 0x00000008
#define HAL_SRNG_RING_PTR_SWAP 0x00000010
#define HAL_SRNG_DATA_TLV_SWAP 0x00000020
#define HAL_SRNG_LOW_THRES_INTR_ENABLE 0x00010000
#define HAL_SRNG_MSI_INTR 0x00020000
#define HAL_SRNG_CACHED_DESC 0x00040000
#ifdef QCA_WIFI_QCA6490
#define HAL_SRNG_PREFETCH_TIMER 1
#else
#define HAL_SRNG_PREFETCH_TIMER 0
#endif
#define PN_SIZE_24 0
#define PN_SIZE_48 1
#define PN_SIZE_128 2
#ifdef FORCE_WAKE
/**
* hal_set_init_phase() - Indicate initialization of
* datapath rings
* @soc: hal_soc handle
* @init_phase: flag to indicate datapath rings
* initialization status
*
* Return: None
*/
void hal_set_init_phase(hal_soc_handle_t soc, bool init_phase);
#else
static inline
void hal_set_init_phase(hal_soc_handle_t soc, bool init_phase)
{
}
#endif /* FORCE_WAKE */
/**
* hal_srng_get_entrysize - Returns size of ring entry in bytes. Should be
* used by callers for calculating the size of memory to be allocated before
* calling hal_srng_setup to setup the ring
*
* @hal_soc: Opaque HAL SOC handle
* @ring_type: one of the types from hal_ring_type
*
*/
extern uint32_t hal_srng_get_entrysize(void *hal_soc, int ring_type);
/**
* hal_srng_max_entries - Returns maximum possible number of ring entries
* @hal_soc: Opaque HAL SOC handle
* @ring_type: one of the types from hal_ring_type
*
* Return: Maximum number of entries for the given ring_type
*/
uint32_t hal_srng_max_entries(void *hal_soc, int ring_type);
/**
* hal_srng_dump - Dump ring status
* @srng: hal srng pointer
*/
void hal_srng_dump(struct hal_srng *srng);
/**
* hal_srng_get_dir - Returns the direction of the ring
* @hal_soc: Opaque HAL SOC handle
* @ring_type: one of the types from hal_ring_type
*
* Return: Ring direction
*/
enum hal_srng_dir hal_srng_get_dir(void *hal_soc, int ring_type);
/* HAL memory information */
struct hal_mem_info {
/* dev base virutal addr */
void *dev_base_addr;
/* dev base physical addr */
void *dev_base_paddr;
/* Remote virtual pointer memory for HW/FW updates */
void *shadow_rdptr_mem_vaddr;
/* Remote physical pointer memory for HW/FW updates */
void *shadow_rdptr_mem_paddr;
/* Shared memory for ring pointer updates from host to FW */
void *shadow_wrptr_mem_vaddr;
/* Shared physical memory for ring pointer updates from host to FW */
void *shadow_wrptr_mem_paddr;
};
/* SRNG parameters to be passed to hal_srng_setup */
struct hal_srng_params {
/* Physical base address of the ring */
qdf_dma_addr_t ring_base_paddr;
/* Virtual base address of the ring */
void *ring_base_vaddr;
/* Number of entries in ring */
uint32_t num_entries;
/* max transfer length */
uint16_t max_buffer_length;
/* MSI Address */
qdf_dma_addr_t msi_addr;
/* MSI data */
uint32_t msi_data;
/* Interrupt timer threshold – in micro seconds */
uint32_t intr_timer_thres_us;
/* Interrupt batch counter threshold – in number of ring entries */
uint32_t intr_batch_cntr_thres_entries;
/* Low threshold – in number of ring entries
* (valid for src rings only)
*/
uint32_t low_threshold;
/* Misc flags */
uint32_t flags;
/* Unique ring id */
uint8_t ring_id;
/* Source or Destination ring */
enum hal_srng_dir ring_dir;
/* Size of ring entry */
uint32_t entry_size;
/* hw register base address */
void *hwreg_base[MAX_SRNG_REG_GROUPS];
/* prefetch timer config - in micro seconds */
uint32_t prefetch_timer;
};
/* hal_construct_shadow_config() - initialize the shadow registers for dp rings
* @hal_soc: hal handle
*
* Return: QDF_STATUS_OK on success
*/
extern QDF_STATUS hal_construct_shadow_config(void *hal_soc);
/* hal_set_one_shadow_config() - add a config for the specified ring
* @hal_soc: hal handle
* @ring_type: ring type
* @ring_num: ring num
*
* The ring type and ring num uniquely specify the ring. After this call,
* the hp/tp will be added as the next entry int the shadow register
* configuration table. The hal code will use the shadow register address
* in place of the hp/tp address.
*
* This function is exposed, so that the CE module can skip configuring shadow
* registers for unused ring and rings assigned to the firmware.
*
* Return: QDF_STATUS_OK on success
*/
extern QDF_STATUS hal_set_one_shadow_config(void *hal_soc, int ring_type,
int ring_num);
/**
* hal_get_shadow_config() - retrieve the config table
* @hal_soc: hal handle
* @shadow_config: will point to the table after
* @num_shadow_registers_configured: will contain the number of valid entries
*/
extern void hal_get_shadow_config(void *hal_soc,
struct pld_shadow_reg_v2_cfg **shadow_config,
int *num_shadow_registers_configured);
/**
* hal_srng_setup - Initialize HW SRNG ring.
*
* @hal_soc: Opaque HAL SOC handle
* @ring_type: one of the types from hal_ring_type
* @ring_num: Ring number if there are multiple rings of
* same type (staring from 0)
* @mac_id: valid MAC Id should be passed if ring type is one of lmac rings
* @ring_params: SRNG ring params in hal_srng_params structure.
* Callers are expected to allocate contiguous ring memory of size
* 'num_entries * entry_size' bytes and pass the physical and virtual base
* addresses through 'ring_base_paddr' and 'ring_base_vaddr' in hal_srng_params
* structure. Ring base address should be 8 byte aligned and size of each ring
* entry should be queried using the API hal_srng_get_entrysize
*
* Return: Opaque pointer to ring on success
* NULL on failure (if given ring is not available)
*/
extern void *hal_srng_setup(void *hal_soc, int ring_type, int ring_num,
int mac_id, struct hal_srng_params *ring_params);
/* Remapping ids of REO rings */
#define REO_REMAP_TCL 0
#define REO_REMAP_SW1 1
#define REO_REMAP_SW2 2
#define REO_REMAP_SW3 3
#define REO_REMAP_SW4 4
#define REO_REMAP_RELEASE 5
#define REO_REMAP_FW 6
#define REO_REMAP_UNUSED 7
/*
* Macro to access HWIO_REO_R0_ERROR_DESTINATION_RING_CTRL_IX_0
* to map destination to rings
*/
#define HAL_REO_ERR_REMAP_IX0(_VALUE, _OFFSET) \
((_VALUE) << \
(HWIO_REO_R0_ERROR_DESTINATION_MAPPING_IX_0_ERROR_ ## \
DESTINATION_RING_ ## _OFFSET ## _SHFT))
/*
* Macro to access HWIO_REO_R0_DESTINATION_RING_CTRL_IX_0
* to map destination to rings
*/
#define HAL_REO_REMAP_IX0(_VALUE, _OFFSET) \
((_VALUE) << \
(HWIO_REO_R0_DESTINATION_RING_CTRL_IX_0_DEST_RING_MAPPING_ ## \
_OFFSET ## _SHFT))
/*
* Macro to access HWIO_REO_R0_DESTINATION_RING_CTRL_IX_1
* to map destination to rings
*/
#define HAL_REO_REMAP_IX2(_VALUE, _OFFSET) \
((_VALUE) << \
(HWIO_REO_R0_DESTINATION_RING_CTRL_IX_2_DEST_RING_MAPPING_ ## \
_OFFSET ## _SHFT))
/*
* Macro to access HWIO_REO_R0_DESTINATION_RING_CTRL_IX_3
* to map destination to rings
*/
#define HAL_REO_REMAP_IX3(_VALUE, _OFFSET) \
((_VALUE) << \
(HWIO_REO_R0_DESTINATION_RING_CTRL_IX_3_DEST_RING_MAPPING_ ## \
_OFFSET ## _SHFT))
/**
* hal_reo_read_write_ctrl_ix - Read or write REO_DESTINATION_RING_CTRL_IX
* @hal_soc_hdl: HAL SOC handle
* @read: boolean value to indicate if read or write
* @ix0: pointer to store IX0 reg value
* @ix1: pointer to store IX1 reg value
* @ix2: pointer to store IX2 reg value
* @ix3: pointer to store IX3 reg value
*/
void hal_reo_read_write_ctrl_ix(hal_soc_handle_t hal_soc_hdl, bool read,
uint32_t *ix0, uint32_t *ix1,
uint32_t *ix2, uint32_t *ix3);
/**
* hal_srng_set_hp_paddr() - Set physical address to dest SRNG head pointer
* @sring: sring pointer
* @paddr: physical address
*/
extern void hal_srng_dst_set_hp_paddr(struct hal_srng *sring, uint64_t paddr);
/**
* hal_srng_dst_init_hp() - Initilaize head pointer with cached head pointer
* @srng: sring pointer
* @vaddr: virtual address
*/
extern void hal_srng_dst_init_hp(struct hal_srng *srng, uint32_t *vaddr);
/**
* hal_srng_cleanup - Deinitialize HW SRNG ring.
* @hal_soc: Opaque HAL SOC handle
* @hal_srng: Opaque HAL SRNG pointer
*/
void hal_srng_cleanup(void *hal_soc, hal_ring_handle_t hal_ring_hdl);
static inline bool hal_srng_initialized(hal_ring_handle_t hal_ring_hdl)
{
struct hal_srng *srng = (struct hal_srng *)hal_ring_hdl;
return !!srng->initialized;
}
/**
* hal_srng_dst_peek - Check if there are any entries in the ring (peek)
* @hal_soc: Opaque HAL SOC handle
* @hal_ring_hdl: Destination ring pointer
*
* Caller takes responsibility for any locking needs.
*
* Return: Opaque pointer for next ring entry; NULL on failire
*/
static inline
void *hal_srng_dst_peek(hal_soc_handle_t hal_soc_hdl,
hal_ring_handle_t hal_ring_hdl)
{
struct hal_srng *srng = (struct hal_srng *)hal_ring_hdl;
if (srng->u.dst_ring.tp != srng->u.dst_ring.cached_hp)
return (void *)(&srng->ring_base_vaddr[srng->u.dst_ring.tp]);
return NULL;
}
/**
* hal_srng_access_start_unlocked - Start ring access (unlocked). Should use
* hal_srng_access_start if locked access is required
*
* @hal_soc: Opaque HAL SOC handle
* @hal_ring_hdl: Ring pointer (Source or Destination ring)
*
* Return: 0 on success; error on failire
*/
static inline int
hal_srng_access_start_unlocked(hal_soc_handle_t hal_soc_hdl,
hal_ring_handle_t hal_ring_hdl)
{
struct hal_srng *srng = (struct hal_srng *)hal_ring_hdl;
struct hal_soc *soc = (struct hal_soc *)hal_soc_hdl;
uint32_t *desc;
if (srng->ring_dir == HAL_SRNG_SRC_RING)
srng->u.src_ring.cached_tp =
*(volatile uint32_t *)(srng->u.src_ring.tp_addr);
else {
srng->u.dst_ring.cached_hp =
*(volatile uint32_t *)(srng->u.dst_ring.hp_addr);
if (srng->flags & HAL_SRNG_CACHED_DESC) {
desc = hal_srng_dst_peek(hal_soc_hdl, hal_ring_hdl);
if (qdf_likely(desc)) {
qdf_mem_dma_cache_sync(soc->qdf_dev,
qdf_mem_virt_to_phys
(desc),
QDF_DMA_FROM_DEVICE,
(srng->entry_size *
sizeof(uint32_t)));
qdf_prefetch(desc);
}
}
}
return 0;
}
/**
* hal_srng_access_start - Start (locked) ring access
*
* @hal_soc: Opaque HAL SOC handle
* @hal_ring_hdl: Ring pointer (Source or Destination ring)
*
* Return: 0 on success; error on failire
*/
static inline int hal_srng_access_start(hal_soc_handle_t hal_soc_hdl,
hal_ring_handle_t hal_ring_hdl)
{
struct hal_srng *srng = (struct hal_srng *)hal_ring_hdl;
if (qdf_unlikely(!hal_ring_hdl)) {
qdf_print("Error: Invalid hal_ring\n");
return -EINVAL;
}
SRNG_LOCK(&(srng->lock));
return hal_srng_access_start_unlocked(hal_soc_hdl, hal_ring_hdl);
}
/**
* hal_srng_dst_get_next - Get next entry from a destination ring and move
* cached tail pointer
*
* @hal_soc: Opaque HAL SOC handle
* @hal_ring_hdl: Destination ring pointer
*
* Return: Opaque pointer for next ring entry; NULL on failire
*/
static inline
void *hal_srng_dst_get_next(void *hal_soc,
hal_ring_handle_t hal_ring_hdl)
{
struct hal_srng *srng = (struct hal_srng *)hal_ring_hdl;
struct hal_soc *soc = (struct hal_soc *)hal_soc;
uint32_t *desc;
uint32_t *desc_next;
uint32_t tp;
if (srng->u.dst_ring.tp != srng->u.dst_ring.cached_hp) {
desc = &(srng->ring_base_vaddr[srng->u.dst_ring.tp]);
/* TODO: Using % is expensive, but we have to do this since
* size of some SRNG rings is not power of 2 (due to descriptor
* sizes). Need to create separate API for rings used
* per-packet, with sizes power of 2 (TCL2SW, REO2SW,
* SW2RXDMA and CE rings)
*/
srng->u.dst_ring.tp = (srng->u.dst_ring.tp + srng->entry_size) %
srng->ring_size;
if (srng->flags & HAL_SRNG_CACHED_DESC) {
tp = srng->u.dst_ring.tp;
desc_next = &srng->ring_base_vaddr[tp];
qdf_mem_dma_cache_sync(soc->qdf_dev,
qdf_mem_virt_to_phys(desc_next),
QDF_DMA_FROM_DEVICE,
(srng->entry_size *
sizeof(uint32_t)));
qdf_prefetch(desc_next);
}
return (void *)desc;
}
return NULL;
}
/**
* hal_srng_dst_get_next_hp - Get next entry from a destination ring and move
* cached head pointer
*
* @hal_soc: Opaque HAL SOC handle
* @hal_ring_hdl: Destination ring pointer
*
* Return: Opaque pointer for next ring entry; NULL on failire
*/
static inline void *
hal_srng_dst_get_next_hp(hal_soc_handle_t hal_soc_hdl,
hal_ring_handle_t hal_ring_hdl)
{
struct hal_srng *srng = (struct hal_srng *)hal_ring_hdl;
uint32_t *desc;
/* TODO: Using % is expensive, but we have to do this since
* size of some SRNG rings is not power of 2 (due to descriptor
* sizes). Need to create separate API for rings used
* per-packet, with sizes power of 2 (TCL2SW, REO2SW,
* SW2RXDMA and CE rings)
*/
uint32_t next_hp = (srng->u.dst_ring.cached_hp + srng->entry_size) %
srng->ring_size;
if (next_hp != srng->u.dst_ring.tp) {
desc = &(srng->ring_base_vaddr[srng->u.dst_ring.cached_hp]);
srng->u.dst_ring.cached_hp = next_hp;
return (void *)desc;
}
return NULL;
}
/**
* hal_srng_dst_peek_sync - Check if there are any entries in the ring (peek)
* @hal_soc: Opaque HAL SOC handle
* @hal_ring_hdl: Destination ring pointer
*
* Sync cached head pointer with HW.
* Caller takes responsibility for any locking needs.
*
* Return: Opaque pointer for next ring entry; NULL on failire
*/
static inline
void *hal_srng_dst_peek_sync(hal_soc_handle_t hal_soc_hdl,
hal_ring_handle_t hal_ring_hdl)
{
struct hal_srng *srng = (struct hal_srng *)hal_ring_hdl;
srng->u.dst_ring.cached_hp =
*(volatile uint32_t *)(srng->u.dst_ring.hp_addr);
if (srng->u.dst_ring.tp != srng->u.dst_ring.cached_hp)
return (void *)(&(srng->ring_base_vaddr[srng->u.dst_ring.tp]));
return NULL;
}
/**
* hal_srng_dst_peek_sync_locked - Peek for any entries in the ring
* @hal_soc: Opaque HAL SOC handle
* @hal_ring_hdl: Destination ring pointer
*
* Sync cached head pointer with HW.
* This function takes up SRNG_LOCK. Should not be called with SRNG lock held.
*
* Return: Opaque pointer for next ring entry; NULL on failire
*/
static inline
void *hal_srng_dst_peek_sync_locked(hal_soc_handle_t hal_soc_hdl,
hal_ring_handle_t hal_ring_hdl)
{
struct hal_srng *srng = (struct hal_srng *)hal_ring_hdl;
void *ring_desc_ptr = NULL;
if (qdf_unlikely(!hal_ring_hdl)) {
qdf_print("Error: Invalid hal_ring\n");
return NULL;
}
SRNG_LOCK(&srng->lock);
ring_desc_ptr = hal_srng_dst_peek_sync(hal_soc_hdl, hal_ring_hdl);
SRNG_UNLOCK(&srng->lock);
return ring_desc_ptr;
}
/**
* hal_srng_dst_num_valid - Returns number of valid entries (to be processed
* by SW) in destination ring
*
* @hal_soc: Opaque HAL SOC handle
* @hal_ring_hdl: Destination ring pointer
* @sync_hw_ptr: Sync cached head pointer with HW
*
*/
static inline
uint32_t hal_srng_dst_num_valid(void *hal_soc,
hal_ring_handle_t hal_ring_hdl,
int sync_hw_ptr)
{
struct hal_srng *srng = (struct hal_srng *)hal_ring_hdl;
uint32_t hp;
uint32_t tp = srng->u.dst_ring.tp;
if (sync_hw_ptr) {
hp = *(volatile uint32_t *)(srng->u.dst_ring.hp_addr);
srng->u.dst_ring.cached_hp = hp;
} else {
hp = srng->u.dst_ring.cached_hp;
}
if (hp >= tp)
return (hp - tp) / srng->entry_size;
else
return (srng->ring_size - tp + hp) / srng->entry_size;
}
/**
* hal_srng_dst_num_valid_locked - Returns num valid entries to be processed
*
* @hal_soc: Opaque HAL SOC handle
* @hal_ring_hdl: Destination ring pointer
* @sync_hw_ptr: Sync cached head pointer with HW
*
* Returns number of valid entries to be processed by the host driver. The
* function takes up SRNG lock.
*
* Return: Number of valid destination entries
*/
static inline uint32_t
hal_srng_dst_num_valid_locked(hal_soc_handle_t hal_soc,
hal_ring_handle_t hal_ring_hdl,
int sync_hw_ptr)
{
uint32_t num_valid;
struct hal_srng *srng = (struct hal_srng *)hal_ring_hdl;
SRNG_LOCK(&srng->lock);
num_valid = hal_srng_dst_num_valid(hal_soc, hal_ring_hdl, sync_hw_ptr);
SRNG_UNLOCK(&srng->lock);
return num_valid;
}
/**
* hal_srng_src_reap_next - Reap next entry from a source ring and move reap
* pointer. This can be used to release any buffers associated with completed
* ring entries. Note that this should not be used for posting new descriptor
* entries. Posting of new entries should be done only using
* hal_srng_src_get_next_reaped when this function is used for reaping.
*
* @hal_soc: Opaque HAL SOC handle
* @hal_ring_hdl: Source ring pointer
*
* Return: Opaque pointer for next ring entry; NULL on failire
*/
static inline void *
hal_srng_src_reap_next(void *hal_soc, hal_ring_handle_t hal_ring_hdl)
{
struct hal_srng *srng = (struct hal_srng *)hal_ring_hdl;
uint32_t *desc;
/* TODO: Using % is expensive, but we have to do this since
* size of some SRNG rings is not power of 2 (due to descriptor
* sizes). Need to create separate API for rings used
* per-packet, with sizes power of 2 (TCL2SW, REO2SW,
* SW2RXDMA and CE rings)
*/
uint32_t next_reap_hp = (srng->u.src_ring.reap_hp + srng->entry_size) %
srng->ring_size;
if (next_reap_hp != srng->u.src_ring.cached_tp) {
desc = &(srng->ring_base_vaddr[next_reap_hp]);
srng->u.src_ring.reap_hp = next_reap_hp;
return (void *)desc;
}
return NULL;
}
/**
* hal_srng_src_get_next_reaped - Get next entry from a source ring that is
* already reaped using hal_srng_src_reap_next, for posting new entries to
* the ring
*
* @hal_soc: Opaque HAL SOC handle
* @hal_ring_hdl: Source ring pointer
*
* Return: Opaque pointer for next (reaped) source ring entry; NULL on failire
*/
static inline void *
hal_srng_src_get_next_reaped(void *hal_soc, hal_ring_handle_t hal_ring_hdl)
{
struct hal_srng *srng = (struct hal_srng *)hal_ring_hdl;
uint32_t *desc;
if (srng->u.src_ring.hp != srng->u.src_ring.reap_hp) {
desc = &(srng->ring_base_vaddr[srng->u.src_ring.hp]);
srng->u.src_ring.hp = (srng->u.src_ring.hp + srng->entry_size) %
srng->ring_size;
return (void *)desc;
}
return NULL;
}
/**
* hal_srng_src_pending_reap_next - Reap next entry from a source ring and
* move reap pointer. This API is used in detach path to release any buffers
* associated with ring entries which are pending reap.
*
* @hal_soc: Opaque HAL SOC handle
* @hal_ring_hdl: Source ring pointer
*
* Return: Opaque pointer for next ring entry; NULL on failire
*/
static inline void *
hal_srng_src_pending_reap_next(void *hal_soc, hal_ring_handle_t hal_ring_hdl)
{
struct hal_srng *srng = (struct hal_srng *)hal_ring_hdl;
uint32_t *desc;
uint32_t next_reap_hp = (srng->u.src_ring.reap_hp + srng->entry_size) %
srng->ring_size;
if (next_reap_hp != srng->u.src_ring.hp) {
desc = &(srng->ring_base_vaddr[next_reap_hp]);
srng->u.src_ring.reap_hp = next_reap_hp;
return (void *)desc;
}
return NULL;
}
/**
* hal_srng_src_done_val -
*
* @hal_soc: Opaque HAL SOC handle
* @hal_ring_hdl: Source ring pointer
*
* Return: Opaque pointer for next ring entry; NULL on failire
*/
static inline uint32_t
hal_srng_src_done_val(void *hal_soc, hal_ring_handle_t hal_ring_hdl)
{
struct hal_srng *srng = (struct hal_srng *)hal_ring_hdl;
/* TODO: Using % is expensive, but we have to do this since
* size of some SRNG rings is not power of 2 (due to descriptor
* sizes). Need to create separate API for rings used
* per-packet, with sizes power of 2 (TCL2SW, REO2SW,
* SW2RXDMA and CE rings)
*/
uint32_t next_reap_hp = (srng->u.src_ring.reap_hp + srng->entry_size) %
srng->ring_size;
if (next_reap_hp == srng->u.src_ring.cached_tp)
return 0;
if (srng->u.src_ring.cached_tp > next_reap_hp)
return (srng->u.src_ring.cached_tp - next_reap_hp) /
srng->entry_size;
else
return ((srng->ring_size - next_reap_hp) +
srng->u.src_ring.cached_tp) / srng->entry_size;
}
/**
* hal_get_entrysize_from_srng() - Retrieve ring entry size
* @hal_ring_hdl: Source ring pointer
*
* Return: uint8_t
*/
static inline
uint8_t hal_get_entrysize_from_srng(hal_ring_handle_t hal_ring_hdl)
{
struct hal_srng *srng = (struct hal_srng *)hal_ring_hdl;
return srng->entry_size;
}
/**
* hal_get_sw_hptp - Get SW head and tail pointer location for any ring
* @hal_soc: Opaque HAL SOC handle
* @hal_ring_hdl: Source ring pointer
* @tailp: Tail Pointer
* @headp: Head Pointer
*
* Return: Update tail pointer and head pointer in arguments.
*/
static inline
void hal_get_sw_hptp(void *hal_soc, hal_ring_handle_t hal_ring_hdl,
uint32_t *tailp, uint32_t *headp)
{
struct hal_srng *srng = (struct hal_srng *)hal_ring_hdl;
if (srng->ring_dir == HAL_SRNG_SRC_RING) {
*headp = srng->u.src_ring.hp;
*tailp = *srng->u.src_ring.tp_addr;
} else {
*tailp = srng->u.dst_ring.tp;
*headp = *srng->u.dst_ring.hp_addr;
}
}
/**
* hal_srng_src_get_next - Get next entry from a source ring and move cached tail pointer
*
* @hal_soc: Opaque HAL SOC handle
* @hal_ring_hdl: Source ring pointer
*
* Return: Opaque pointer for next ring entry; NULL on failire
*/
static inline
void *hal_srng_src_get_next(void *hal_soc,
hal_ring_handle_t hal_ring_hdl)
{
struct hal_srng *srng = (struct hal_srng *)hal_ring_hdl;
uint32_t *desc;
/* TODO: Using % is expensive, but we have to do this since
* size of some SRNG rings is not power of 2 (due to descriptor
* sizes). Need to create separate API for rings used
* per-packet, with sizes power of 2 (TCL2SW, REO2SW,
* SW2RXDMA and CE rings)
*/
uint32_t next_hp = (srng->u.src_ring.hp + srng->entry_size) %
srng->ring_size;
if (next_hp != srng->u.src_ring.cached_tp) {
desc = &(srng->ring_base_vaddr[srng->u.src_ring.hp]);
srng->u.src_ring.hp = next_hp;
/* TODO: Since reap function is not used by all rings, we can
* remove the following update of reap_hp in this function
* if we can ensure that only hal_srng_src_get_next_reaped
* is used for the rings requiring reap functionality
*/
srng->u.src_ring.reap_hp = next_hp;
return (void *)desc;
}
return NULL;
}
/**
* hal_srng_src_peek - Get next entry from a ring without moving head pointer.
* hal_srng_src_get_next should be called subsequently to move the head pointer
*
* @hal_soc: Opaque HAL SOC handle
* @hal_ring_hdl: Source ring pointer
*
* Return: Opaque pointer for next ring entry; NULL on failire
*/
static inline
void *hal_srng_src_peek(hal_soc_handle_t hal_soc_hdl,
hal_ring_handle_t hal_ring_hdl)
{
struct hal_srng *srng = (struct hal_srng *)hal_ring_hdl;
uint32_t *desc;
/* TODO: Using % is expensive, but we have to do this since
* size of some SRNG rings is not power of 2 (due to descriptor
* sizes). Need to create separate API for rings used
* per-packet, with sizes power of 2 (TCL2SW, REO2SW,
* SW2RXDMA and CE rings)
*/
if (((srng->u.src_ring.hp + srng->entry_size) %
srng->ring_size) != srng->u.src_ring.cached_tp) {
desc = &(srng->ring_base_vaddr[srng->u.src_ring.hp]);
return (void *)desc;
}
return NULL;
}
/**
* hal_srng_src_num_avail - Returns number of available entries in src ring
*
* @hal_soc: Opaque HAL SOC handle
* @hal_ring_hdl: Source ring pointer
* @sync_hw_ptr: Sync cached tail pointer with HW
*
*/
static inline uint32_t
hal_srng_src_num_avail(void *hal_soc,
hal_ring_handle_t hal_ring_hdl, int sync_hw_ptr)
{
struct hal_srng *srng = (struct hal_srng *)hal_ring_hdl;
uint32_t tp;
uint32_t hp = srng->u.src_ring.hp;
if (sync_hw_ptr) {
tp = *(srng->u.src_ring.tp_addr);
srng->u.src_ring.cached_tp = tp;
} else {
tp = srng->u.src_ring.cached_tp;
}
if (tp > hp)
return ((tp - hp) / srng->entry_size) - 1;
else
return ((srng->ring_size - hp + tp) / srng->entry_size) - 1;
}
/**
* hal_srng_access_end_unlocked - End ring access (unlocked) - update cached
* ring head/tail pointers to HW.
* This should be used only if hal_srng_access_start_unlocked to start ring
* access
*
* @hal_soc: Opaque HAL SOC handle
* @hal_ring_hdl: Ring pointer (Source or Destination ring)
*
* Return: 0 on success; error on failire
*/
static inline void
hal_srng_access_end_unlocked(void *hal_soc, hal_ring_handle_t hal_ring_hdl)
{
struct hal_srng *srng = (struct hal_srng *)hal_ring_hdl;
/* TODO: See if we need a write memory barrier here */
if (srng->flags & HAL_SRNG_LMAC_RING) {
/* For LMAC rings, ring pointer updates are done through FW and
* hence written to a shared memory location that is read by FW
*/
if (srng->ring_dir == HAL_SRNG_SRC_RING) {
*(srng->u.src_ring.hp_addr) = srng->u.src_ring.hp;
} else {
*(srng->u.dst_ring.tp_addr) = srng->u.dst_ring.tp;
}
} else {
if (srng->ring_dir == HAL_SRNG_SRC_RING)
hal_srng_write_address_32_mb(hal_soc,
srng,
srng->u.src_ring.hp_addr,
srng->u.src_ring.hp);
else
hal_srng_write_address_32_mb(hal_soc,
srng,
srng->u.dst_ring.tp_addr,
srng->u.dst_ring.tp);
}
}
/**
* hal_srng_access_end - Unlock ring access and update cached ring head/tail
* pointers to HW
* This should be used only if hal_srng_access_start to start ring access
*
* @hal_soc: Opaque HAL SOC handle
* @hal_ring_hdl: Ring pointer (Source or Destination ring)
*
* Return: 0 on success; error on failire
*/
static inline void
hal_srng_access_end(void *hal_soc, hal_ring_handle_t hal_ring_hdl)
{
struct hal_srng *srng = (struct hal_srng *)hal_ring_hdl;
if (qdf_unlikely(!hal_ring_hdl)) {
qdf_print("Error: Invalid hal_ring\n");
return;
}
hal_srng_access_end_unlocked(hal_soc, hal_ring_hdl);
SRNG_UNLOCK(&(srng->lock));
}
/**
* hal_srng_access_end_reap - Unlock ring access
* This should be used only if hal_srng_access_start to start ring access
* and should be used only while reaping SRC ring completions
*
* @hal_soc: Opaque HAL SOC handle
* @hal_ring_hdl: Ring pointer (Source or Destination ring)
*
* Return: 0 on success; error on failire
*/
static inline void
hal_srng_access_end_reap(void *hal_soc, hal_ring_handle_t hal_ring_hdl)
{
struct hal_srng *srng = (struct hal_srng *)hal_ring_hdl;
SRNG_UNLOCK(&(srng->lock));
}
/* TODO: Check if the following definitions is available in HW headers */
#define WBM_IDLE_SCATTER_BUF_SIZE 32704
#define NUM_MPDUS_PER_LINK_DESC 6
#define NUM_MSDUS_PER_LINK_DESC 7
#define REO_QUEUE_DESC_ALIGN 128
#define LINK_DESC_ALIGN 128
#define ADDRESS_MATCH_TAG_VAL 0x5
/* Number of mpdu link pointers is 9 in case of TX_MPDU_QUEUE_HEAD and 14 in
* of TX_MPDU_QUEUE_EXT. We are defining a common average count here
*/
#define NUM_MPDU_LINKS_PER_QUEUE_DESC 12
/* TODO: Check with HW team on the scatter buffer size supported. As per WBM
* MLD, scatter_buffer_size in IDLE_LIST_CONTROL register is 9 bits and size
* should be specified in 16 word units. But the number of bits defined for
* this field in HW header files is 5.
*/
#define WBM_IDLE_SCATTER_BUF_NEXT_PTR_SIZE 8
/**
* hal_idle_list_scatter_buf_size - Get the size of each scatter buffer
* in an idle list
*
* @hal_soc: Opaque HAL SOC handle
*
*/
static inline
uint32_t hal_idle_list_scatter_buf_size(hal_soc_handle_t hal_soc_hdl)
{
return WBM_IDLE_SCATTER_BUF_SIZE;
}
/**
* hal_get_link_desc_size - Get the size of each link descriptor
*
* @hal_soc: Opaque HAL SOC handle
*
*/
static inline uint32_t hal_get_link_desc_size(hal_soc_handle_t hal_soc_hdl)
{
struct hal_soc *hal_soc = (struct hal_soc *)hal_soc_hdl;
if (!hal_soc || !hal_soc->ops) {
qdf_print("Error: Invalid ops\n");
QDF_BUG(0);
return -EINVAL;
}
if (!hal_soc->ops->hal_get_link_desc_size) {
qdf_print("Error: Invalid function pointer\n");
QDF_BUG(0);
return -EINVAL;
}
return hal_soc->ops->hal_get_link_desc_size();
}
/**
* hal_get_link_desc_align - Get the required start address alignment for
* link descriptors
*
* @hal_soc: Opaque HAL SOC handle
*
*/
static inline
uint32_t hal_get_link_desc_align(hal_soc_handle_t hal_soc_hdl)
{
return LINK_DESC_ALIGN;
}
/**
* hal_num_mpdus_per_link_desc - Get number of mpdus each link desc can hold
*
* @hal_soc: Opaque HAL SOC handle
*
*/
static inline
uint32_t hal_num_mpdus_per_link_desc(hal_soc_handle_t hal_soc_hdl)
{
return NUM_MPDUS_PER_LINK_DESC;
}
/**
* hal_num_msdus_per_link_desc - Get number of msdus each link desc can hold
*
* @hal_soc: Opaque HAL SOC handle
*
*/
static inline
uint32_t hal_num_msdus_per_link_desc(hal_soc_handle_t hal_soc_hdl)
{
return NUM_MSDUS_PER_LINK_DESC;
}
/**
* hal_num_mpdu_links_per_queue_desc - Get number of mpdu links each queue
* descriptor can hold
*
* @hal_soc: Opaque HAL SOC handle
*
*/
static inline
uint32_t hal_num_mpdu_links_per_queue_desc(hal_soc_handle_t hal_soc_hdl)
{
return NUM_MPDU_LINKS_PER_QUEUE_DESC;
}
/**
* hal_idle_list_scatter_buf_num_entries - Get the number of link desc entries
* that the given buffer size
*
* @hal_soc: Opaque HAL SOC handle
* @scatter_buf_size: Size of scatter buffer
*
*/
static inline
uint32_t hal_idle_scatter_buf_num_entries(hal_soc_handle_t hal_soc_hdl,
uint32_t scatter_buf_size)
{
return (scatter_buf_size - WBM_IDLE_SCATTER_BUF_NEXT_PTR_SIZE) /
hal_srng_get_entrysize(hal_soc_hdl, WBM_IDLE_LINK);
}
/**
* hal_idle_list_num_scatter_bufs - Get the number of sctater buffer
* each given buffer size
*
* @hal_soc: Opaque HAL SOC handle
* @total_mem: size of memory to be scattered
* @scatter_buf_size: Size of scatter buffer
*
*/
static inline
uint32_t hal_idle_list_num_scatter_bufs(hal_soc_handle_t hal_soc_hdl,
uint32_t total_mem,
uint32_t scatter_buf_size)
{
uint8_t rem = (total_mem % (scatter_buf_size -
WBM_IDLE_SCATTER_BUF_NEXT_PTR_SIZE)) ? 1 : 0;
uint32_t num_scatter_bufs = (total_mem / (scatter_buf_size -
WBM_IDLE_SCATTER_BUF_NEXT_PTR_SIZE)) + rem;
return num_scatter_bufs;
}
enum hal_pn_type {
HAL_PN_NONE,
HAL_PN_WPA,
HAL_PN_WAPI_EVEN,
HAL_PN_WAPI_UNEVEN,
};
#define HAL_RX_MAX_BA_WINDOW 256
/**
* hal_get_reo_qdesc_align - Get start address alignment for reo
* queue descriptors
*
* @hal_soc: Opaque HAL SOC handle
*
*/
static inline
uint32_t hal_get_reo_qdesc_align(hal_soc_handle_t hal_soc_hdl)
{
return REO_QUEUE_DESC_ALIGN;
}
/**
* hal_reo_qdesc_setup - Setup HW REO queue descriptor
*
* @hal_soc: Opaque HAL SOC handle
* @ba_window_size: BlockAck window size
* @start_seq: Starting sequence number
* @hw_qdesc_vaddr: Virtual address of REO queue descriptor memory
* @hw_qdesc_paddr: Physical address of REO queue descriptor memory
* @pn_type: PN type (one of the types defined in 'enum hal_pn_type')
*
*/
void hal_reo_qdesc_setup(hal_soc_handle_t hal_soc_hdl,
int tid, uint32_t ba_window_size,
uint32_t start_seq, void *hw_qdesc_vaddr,
qdf_dma_addr_t hw_qdesc_paddr,
int pn_type);
/**
* hal_srng_get_hp_addr - Get head pointer physical address
*
* @hal_soc: Opaque HAL SOC handle
* @hal_ring_hdl: Ring pointer (Source or Destination ring)
*
*/
static inline qdf_dma_addr_t
hal_srng_get_hp_addr(void *hal_soc,
hal_ring_handle_t hal_ring_hdl)
{
struct hal_srng *srng = (struct hal_srng *)hal_ring_hdl;
struct hal_soc *hal = (struct hal_soc *)hal_soc;
if (srng->ring_dir == HAL_SRNG_SRC_RING) {
return hal->shadow_wrptr_mem_paddr +
((unsigned long)(srng->u.src_ring.hp_addr) -
(unsigned long)(hal->shadow_wrptr_mem_vaddr));
} else {
return hal->shadow_rdptr_mem_paddr +
((unsigned long)(srng->u.dst_ring.hp_addr) -
(unsigned long)(hal->shadow_rdptr_mem_vaddr));
}
}
/**
* hal_srng_get_tp_addr - Get tail pointer physical address
*
* @hal_soc: Opaque HAL SOC handle
* @hal_ring_hdl: Ring pointer (Source or Destination ring)
*
*/
static inline qdf_dma_addr_t
hal_srng_get_tp_addr(void *hal_soc, hal_ring_handle_t hal_ring_hdl)
{
struct hal_srng *srng = (struct hal_srng *)hal_ring_hdl;
struct hal_soc *hal = (struct hal_soc *)hal_soc;
if (srng->ring_dir == HAL_SRNG_SRC_RING) {
return hal->shadow_rdptr_mem_paddr +
((unsigned long)(srng->u.src_ring.tp_addr) -
(unsigned long)(hal->shadow_rdptr_mem_vaddr));
} else {
return hal->shadow_wrptr_mem_paddr +
((unsigned long)(srng->u.dst_ring.tp_addr) -
(unsigned long)(hal->shadow_wrptr_mem_vaddr));
}
}
/**
* hal_srng_get_num_entries - Get total entries in the HAL Srng
*
* @hal_soc: Opaque HAL SOC handle
* @hal_ring_hdl: Ring pointer (Source or Destination ring)
*
* Return: total number of entries in hal ring
*/
static inline
uint32_t hal_srng_get_num_entries(hal_soc_handle_t hal_soc_hdl,
hal_ring_handle_t hal_ring_hdl)
{
struct hal_srng *srng = (struct hal_srng *)hal_ring_hdl;
return srng->num_entries;
}
/**
* hal_get_srng_params - Retrieve SRNG parameters for a given ring from HAL
*
* @hal_soc: Opaque HAL SOC handle
* @hal_ring_hdl: Ring pointer (Source or Destination ring)
* @ring_params: SRNG parameters will be returned through this structure
*/
void hal_get_srng_params(hal_soc_handle_t hal_soc_hdl,
hal_ring_handle_t hal_ring_hdl,
struct hal_srng_params *ring_params);
/**
* hal_mem_info - Retrieve hal memory base address
*
* @hal_soc: Opaque HAL SOC handle
* @mem: pointer to structure to be updated with hal mem info
*/
void hal_get_meminfo(hal_soc_handle_t hal_soc_hdl, struct hal_mem_info *mem);
/**
* hal_get_target_type - Return target type
*
* @hal_soc: Opaque HAL SOC handle
*/
uint32_t hal_get_target_type(hal_soc_handle_t hal_soc_hdl);
/**
* hal_get_ba_aging_timeout - Retrieve BA aging timeout
*
* @hal_soc: Opaque HAL SOC handle
* @ac: Access category
* @value: timeout duration in millisec
*/
void hal_get_ba_aging_timeout(hal_soc_handle_t hal_soc_hdl, uint8_t ac,
uint32_t *value);
/**
* hal_set_aging_timeout - Set BA aging timeout
*
* @hal_soc: Opaque HAL SOC handle
* @ac: Access category in millisec
* @value: timeout duration value
*/
void hal_set_ba_aging_timeout(hal_soc_handle_t hal_soc_hdl, uint8_t ac,
uint32_t value);
/**
* hal_srng_dst_hw_init - Private function to initialize SRNG
* destination ring HW
* @hal_soc: HAL SOC handle
* @srng: SRNG ring pointer
*/
static inline void hal_srng_dst_hw_init(struct hal_soc *hal,
struct hal_srng *srng)
{
hal->ops->hal_srng_dst_hw_init(hal, srng);
}
/**
* hal_srng_src_hw_init - Private function to initialize SRNG
* source ring HW
* @hal_soc: HAL SOC handle
* @srng: SRNG ring pointer
*/
static inline void hal_srng_src_hw_init(struct hal_soc *hal,
struct hal_srng *srng)
{
hal->ops->hal_srng_src_hw_init(hal, srng);
}
/**
* hal_get_hw_hptp() - Get HW head and tail pointer value for any ring
* @hal_soc: Opaque HAL SOC handle
* @hal_ring_hdl: Source ring pointer
* @headp: Head Pointer
* @tailp: Tail Pointer
* @ring_type: Ring
*
* Return: Update tail pointer and head pointer in arguments.
*/
static inline
void hal_get_hw_hptp(hal_soc_handle_t hal_soc_hdl,
hal_ring_handle_t hal_ring_hdl,
uint32_t *headp, uint32_t *tailp,
uint8_t ring_type)
{
struct hal_soc *hal_soc = (struct hal_soc *)hal_soc_hdl;
hal_soc->ops->hal_get_hw_hptp(hal_soc, hal_ring_hdl,
headp, tailp, ring_type);
}
/**
* hal_reo_setup - Initialize HW REO block
*
* @hal_soc: Opaque HAL SOC handle
* @reo_params: parameters needed by HAL for REO config
*/
static inline void hal_reo_setup(hal_soc_handle_t hal_soc_hdl,
void *reoparams)
{
struct hal_soc *hal_soc = (struct hal_soc *)hal_soc_hdl;
hal_soc->ops->hal_reo_setup(hal_soc, reoparams);
}
/**
* hal_setup_link_idle_list - Setup scattered idle list using the
* buffer list provided
*
* @hal_soc: Opaque HAL SOC handle
* @scatter_bufs_base_paddr: Array of physical base addresses
* @scatter_bufs_base_vaddr: Array of virtual base addresses
* @num_scatter_bufs: Number of scatter buffers in the above lists
* @scatter_buf_size: Size of each scatter buffer
* @last_buf_end_offset: Offset to the last entry
* @num_entries: Total entries of all scatter bufs
*
*/
static inline
void hal_setup_link_idle_list(hal_soc_handle_t hal_soc_hdl,
qdf_dma_addr_t scatter_bufs_base_paddr[],
void *scatter_bufs_base_vaddr[],
uint32_t num_scatter_bufs,
uint32_t scatter_buf_size,
uint32_t last_buf_end_offset,
uint32_t num_entries)
{
struct hal_soc *hal_soc = (struct hal_soc *)hal_soc_hdl;
hal_soc->ops->hal_setup_link_idle_list(hal_soc, scatter_bufs_base_paddr,
scatter_bufs_base_vaddr, num_scatter_bufs,
scatter_buf_size, last_buf_end_offset,
num_entries);
}
/**
* hal_srng_dump_ring_desc() - Dump ring descriptor info
*
* @hal_soc: Opaque HAL SOC handle
* @hal_ring_hdl: Source ring pointer
* @ring_desc: Opaque ring descriptor handle
*/
static inline void hal_srng_dump_ring_desc(hal_soc_handle_t hal_soc_hdl,
hal_ring_handle_t hal_ring_hdl,
hal_ring_desc_t ring_desc)
{
struct hal_srng *srng = (struct hal_srng *)hal_ring_hdl;
QDF_TRACE_HEX_DUMP(QDF_MODULE_ID_DP, QDF_TRACE_LEVEL_INFO_HIGH,
ring_desc, (srng->entry_size << 2));
}
/**
* hal_srng_dump_ring() - Dump last 128 descs of the ring
*
* @hal_soc: Opaque HAL SOC handle
* @hal_ring_hdl: Source ring pointer
*/
static inline void hal_srng_dump_ring(hal_soc_handle_t hal_soc_hdl,
hal_ring_handle_t hal_ring_hdl)
{
struct hal_srng *srng = (struct hal_srng *)hal_ring_hdl;
uint32_t *desc;
uint32_t tp, i;
tp = srng->u.dst_ring.tp;
for (i = 0; i < 128; i++) {
if (!tp)
tp = srng->ring_size;
desc = &srng->ring_base_vaddr[tp - srng->entry_size];
QDF_TRACE_HEX_DUMP(QDF_MODULE_ID_DP,
QDF_TRACE_LEVEL_DEBUG,
desc, (srng->entry_size << 2));
tp -= srng->entry_size;
}
}
/*
* hal_rxdma_desc_to_hal_ring_desc - API to convert rxdma ring desc
* to opaque dp_ring desc type
* @ring_desc - rxdma ring desc
*
* Return: hal_rxdma_desc_t type
*/
static inline
hal_ring_desc_t hal_rxdma_desc_to_hal_ring_desc(hal_rxdma_desc_t ring_desc)
{
return (hal_ring_desc_t)ring_desc;
}
/**
* hal_srng_set_event() - Set hal_srng event
* @hal_ring_hdl: Source ring pointer
* @event: SRNG ring event
*
* Return: None
*/
static inline void hal_srng_set_event(hal_ring_handle_t hal_ring_hdl, int event)
{
struct hal_srng *srng = (struct hal_srng *)hal_ring_hdl;
qdf_atomic_set_bit(event, &srng->srng_event);
}
/**
* hal_srng_clear_event() - Clear hal_srng event
* @hal_ring_hdl: Source ring pointer
* @event: SRNG ring event
*
* Return: None
*/
static inline
void hal_srng_clear_event(hal_ring_handle_t hal_ring_hdl, int event)
{
struct hal_srng *srng = (struct hal_srng *)hal_ring_hdl;
qdf_atomic_clear_bit(event, &srng->srng_event);
}
/**
* hal_srng_get_clear_event() - Clear srng event and return old value
* @hal_ring_hdl: Source ring pointer
* @event: SRNG ring event
*
* Return: Return old event value
*/
static inline
int hal_srng_get_clear_event(hal_ring_handle_t hal_ring_hdl, int event)
{
struct hal_srng *srng = (struct hal_srng *)hal_ring_hdl;
return qdf_atomic_test_and_clear_bit(event, &srng->srng_event);
}
/**
* hal_srng_set_flush_last_ts() - Record last flush time stamp
* @hal_ring_hdl: Source ring pointer
*
* Return: None
*/
static inline void hal_srng_set_flush_last_ts(hal_ring_handle_t hal_ring_hdl)
{
struct hal_srng *srng = (struct hal_srng *)hal_ring_hdl;
srng->last_flush_ts = qdf_get_log_timestamp();
}
/**
* hal_srng_inc_flush_cnt() - Increment flush counter
* @hal_ring_hdl: Source ring pointer
*
* Return: None
*/
static inline void hal_srng_inc_flush_cnt(hal_ring_handle_t hal_ring_hdl)
{
struct hal_srng *srng = (struct hal_srng *)hal_ring_hdl;
srng->flush_count++;
}
/**
* hal_reo_set_err_dst_remap() - Set REO error destination ring remap
* register value.
*
* @hal_soc_hdl: Opaque HAL soc handle
*
* Return: None
*/
static inline void hal_reo_set_err_dst_remap(hal_soc_handle_t hal_soc_hdl)
{
struct hal_soc *hal_soc = (struct hal_soc *)hal_soc_hdl;
if (hal_soc->ops->hal_reo_set_err_dst_remap)
hal_soc->ops->hal_reo_set_err_dst_remap(hal_soc);
}
#endif /* _HAL_APIH_ */